High-Efficiency Zinc-Air Battery
Developed
Stanford University scientists have
developed an advanced zinc-air battery with higher catalytic activity and
durability than similar batteries made with costly platinum and iridium
catalysts. The results, published in the May 7 online edition of the journal Nature
Communications, could lead to the development of a low-cost alternative to
conventional lithium-ion batteries widely used today.
"There have been increasing
demands for high-performance, inexpensive and safe batteries for portable
electronics, electric vehicles and other energy storage applications,"
said Hongjie Dai, a professor chemistry at Stanford and lead author of the
study. "Metal-air batteries offer a possible low-cost solution."
According to Dai, most attention has
focused on lithium-ion batteries, despite their limited energy density (energy
stored per unit volume), high cost and safety problems. "With ample supply
of oxygen from the atmosphere, metal-air batteries have drastically higher
theoretical energy density than either traditional aqueous batteries or
lithium-ion batteries," he said. "Among them, zinc-air is technically
and economically the most viable option."
Zinc-air batteries combine
atmospheric oxygen and zinc metal in a liquid alkaline electrolyte to generate
electricity with a byproduct of zinc oxide. When the process is reversed during
recharging, oxygen and zinc metal are regenerated.
"Zinc-air batteries are
attractive because of the abundance and low cost of zinc metal, as well as the
non-flammable nature of aqueous electrolytes, which make the batteries
inherently safe to operate," Dai said. "Primary (non-rechargeable)
zinc-air batteries have been commercialized for medical and telecommunication
applications with limited power density. However, it remains a grand challenge
to develop electrically rechargeable batteries, with the stumbling blocks being
the lack of efficient and robust air catalysts, as well as the limited cycle
life of the zinc electrodes."
Active and durable electrocatalysts
on the air electrode are required to catalyze the oxygen-reduction reaction
during discharge and the oxygen-evolution reaction during recharge. In zinc-air
batteries, both catalytic reactions are sluggish, Dai said.
Recently, his group has developed a
number of high-performance electrocatalysts made with non-precious metal oxide
or nanocrystals hybridized with carbon nanotubes. These catalysts produced
higher catalytic activity and durability in alkaline electrolytes than
catalysts made with platinum and other precious metals.
"We found that similar
catalysts greatly boosted the performance of zinc-air batteries," Dai
said. both primary and rechargeable. "A combination of a cobalt-oxide
hybrid air catalyst for oxygen reduction and a nickel-iron hydroxide hybrid air
catalyst for oxygen evolution resulted in a record high-energy efficiency for a
zinc-air battery, with a high specific energy density more than twice that of
lithium-ion technology."
The novel battery also demonstrated
good reversibility and stability over long charge and discharge cycles over
several weeks. "This work could be an important step toward developing
practical rechargeable zinc-air batteries, even though other challenges
relating to the zinc electrode and electrolyte remain to be solved," Dai
added.
http://www.sciencedaily.com/releases/2013/05/130529154646.htm
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